Interactive and non-interactive execution and rendering of templates to automate control and exploration across systems

ABSTRACT

The present disclosure relates to platform configured for executing and rendering templates to enable automation of control and data exploration across systems in an interactive and non-interactive mode. Initially, the platform is configured to add template to an exploration either on user request or system driven request and execute the template by extracting execution model associated with the template. Further, the target system is configured to run the execution plan in interactive mode wherein the user may provide inputs or non-interactive mode wherein the target system is configured to run the execution plan without user inputs. The target system is further configured to receive data generated by the target systems in response to the operation executed by the execution engine. On receiving the data from target systems in the data store, the target system is configured to visualize the data on the template rendered on the GUI.

CROSS-REFERENCE TO RELATED APPLICATIONS AND PRIORITY

This application is a National Stage Filing and claims priority from International Application No. PCT/IB2019/050159, filed on Jan. 9, 2019, which application claims priority from Indian Provisional Patent Application No. 201711031962 filed on Jan. 9, 2018 the complete disclosure of which, in its entirety is herein incorporated by reference.

TECHNICAL FIELD

The present disclosure in general relates to the field of interactive and non-interactive execution and rendering of templates to enable automation of control and data exploration across multiple systems.

BACKGROUND

Now a days, with developments in the field of Information Technology (IT), most organizations have multiple disparate systems which contain critical information. These systems largely operate in silos and may have information which is generated by machines or by humans. As a result, users of these systems have to switch applications to view information across these systems, resulting into inefficiency and lower productivity.

For example, in large organizations, there are a number of legacy systems in use, which do not have data analysis and exploration capabilities. Due to this, it becomes difficult to visualize and perform analysis on data in such legacy systems. In addition, it is a tedious and time-consuming job to extract data from databases associated with these legacy systems.

In some scenarios, the data captured by one system cannot be correlated with data captured by another system in the organization. As a result, it becomes very difficult to draw insights and perform analysis on data captured from a set of disconnected systems associated with large organizations.

SUMMARY

This summary is provided to introduce aspects related to platform and methods for executing and rendering templates to enable automation of control and data exploration across multiple systems in an interactive and non-interactive mode and the aspects are further described below in the detailed description. This summary is not intended to identify essential features of the claimed disclosure nor is it intended for use in determining or limiting the scope of the claimed disclosure.

In one embodiment, a platform for interactive and non-interactive execution and rendering of templates is disclosed. The platform comprises a memory and a processor coupled to the memory. The processor is configured to execute program instructions, associated with one or more modules, stored in the memory. In one embodiment, the processor may execute program instructions stored in the memory to establish connection with a set of systems. Further, the processor may execute program instructions stored in the memory to render a new exploration or render an existing exploration over a graphical user interface based on user inputs. Further, the processor may execute program instructions stored in the memory to identify a sub-set of systems from the set of systems based on a context information. Further, the processor may execute program instructions stored in the memory to display a set of operations/operation-groups associated with the sub-set of systems based on the context information. Further, the processor may execute program instructions stored in the memory to identify a target system associated with a target operation/operation-group selected by the user. Further, the processor may execute program instructions stored in the memory to transmit the target operation/operation-group execution request to the target system, wherein the target operation/operation-group is associated with one of a read operation, a write operation to control the target system, or a capture user inputs and perform one of read and write operation to control the target system based on the user inputs. Further, the processor may execute program instructions stored in the memory to receive data from the target system, wherein the data is received in response to execution of the operation or operation-group over the target system. Further, the processor may execute program instructions stored in the memory to discover a subset of best fit templates, from a set of saved templates or templates generated in real-time, based on the type of data received from the target system and a set of predefined rules, wherein the subset of best fit templates enable transmitting data to the target system to write back to the target system to control the target system and receiving data from target system for data visualization. Further, the processor may execute program instructions stored in the memory to generate a notification event, wherein the notification event is indicative of change in the exploration. Further, the processor may execute program instructions stored in the memory to transmit the notification event to one or more listeners interested in the target template. Further, the processor may execute program instructions stored in the memory to render the target template on the new exploration or existing exploration. Further, the processor may execute program instructions stored in the memory to execute the target template by extracting execution model from the target template, wherein the execution model is a graph representing the set of operations stored in a definition of the target template. Further, the processor may execute program instructions stored in the memory to generate instructions to run an execution plan, wherein the execution plan is generated based on the set of operations stored. Further, the processor may execute program instructions stored in the memory to execute each operation from the execution plan in interactive or non-interactive mode. Further, the processor may execute program instructions stored in the memory to prompt the user to provide inputs for a current operation to be executed when user input is required for execution of the operation, wherein an interactive UI element is rendered to capture the user input, wherein each operation from the execution plan is execute based on the user provided inputs. Further, the processor may execute program instructions stored in the memory to receive data generated by the target system in response to the operation executed. Further, the processor may execute program instructions stored in the memory to visualize the data on the template rendered on the GUI based on the data received from target system in the data store.

In one embodiment, a method for interactive and non-interactive execution and rendering of templates is disclosed. The method comprises steps to establish connection with a set of systems. The method further comprises steps to render a new exploration or render an existing exploration over a graphical user interface based on user inputs. The method further comprises steps to identify a sub-set of systems from the set of systems based on a context information. The method further comprises steps to display a set of operations/operation-groups associated with the sub-set of systems based on the context information. The method further comprises steps to identify a target system associated with a target operation/operation-group selected by the user. The method further comprises steps to transmit the target operation/operation-group execution request to the target system, wherein the target operation/operation-group is associated with one of a read operation, a write operation to control the target system, or capture user inputs and perform one of read and write operation to control the target system based on the captured user inputs. The method further comprises steps to receive data from the target system, wherein the data is received in response to execution of the operation or operation-group over the target system. The method further comprises steps to discover a subset of best fit templates, from a set of saved templates or templates generated in real-time, based on the type of data received from the target system and a set of predefined rules, wherein the subset of best fit templates enables transmitting data to the target system to write back to the target system in order to control target system and receiving data from target system for data visualization. The method further comprises steps to generate a notification event, wherein the notification event is indicative of change in the exploration. The method further comprises steps to transmit the notification event to one or more listeners interested in the target template. The method further comprises steps to render the target template on the new exploration or existing exploration. The method further comprises steps to execute the target template by extracting execution model from the target template, wherein the execution model is a graph representing the set of operations stored in a definition of the target template. The method further comprises steps to generate instructions to run an execution plan, wherein the execution plan is generated based on the set of operations stored. The method further comprises steps to execute each operation from the execution plan in interactive or non-interactive mode. The method further comprises steps to prompt the user to provide inputs for a current operation to be executed when user input is required for execution of the operation, wherein an interactive UI element is rendered to capture the user input, wherein each operation from the execution plan is execute based on the user provided inputs. The method further comprises steps to receive data generated by the target system in response to the operation executed. The method further comprises steps to visualize the data on the template rendered on the GUI based on the data received from target system in the data store.

In one embodiment, a computer program product having embodied thereon a computer program for interactive and non-interactive execution and rendering of templates is disclosed. The computer program product comprising a program code to establish connection with a set of systems. The computer program product comprising a program code to render a new exploration or render an existing exploration over a graphical user interface based on user inputs. The computer program product comprising a program code to identify a sub-set of systems from the set of systems based on a context information. The computer program product comprising a program code to display a set of operations/operation-groups associated with the sub-set of systems based on the context information.

The computer program product comprising a program code to identify a target system associated with a target operation/operation-group selected by the user. The computer program product comprising a program code to transmit the target operation/operation-group execution request to the target system, wherein the target operation/operation-group is associated with one of a read operation, a write operation to control the target system, or capture user inputs and perform one of read and write operation to control the target system based on the captured user inputs. The computer program product comprising a program code to receive data from the target system, wherein the data is received in response to execution of the operation or operation-group over the target system. The computer program product comprising a program code to discover a subset of best fit templates, from a set of saved templates or templates generated in real-time, based on the type of data received from the target system and a set of predefined rules, wherein the subset of best fit templates enables transmitting data to the target system to write back to the target system in order to control the target system and receiving data from target system for data visualization. The computer program product comprising a program code to generate a notification event, wherein the notification event is indicative of change in the exploration. The computer program product comprising a program code to transmit the notification event to one or more listeners interested in the target template. The computer program product comprising a program code to render the target template on the new exploration or existing exploration. The computer program product comprising a program code to execute the target template by extracting execution model from the target template, wherein the execution model is a graph representing the set of operations stored in a definition of the target template. The computer program product comprising a program code to generate instructions to run an execution plan, wherein the execution plan is generated based on the set of operations stored. The computer program product comprising a program code to execute each operation from the execution plan in interactive or non-interactive mode. The computer program product comprising a program code to prompt the user to provide inputs for a current operation to be executed when user input is required for execution of the operation, wherein an interactive UI element is rendered to capture the user input, wherein each operation from the execution plan is execute based on the user provided inputs. The computer program product comprising a program code to receive data generated by the target system in response to the operation executed. The computer program product comprising a program code to visualize the data on the template rendered on the GUI based on the data received from target system in the data store.

BRIEF DESCRIPTION OF DRAWINGS

The detailed description is described with reference to the accompanying figures. In the figures, the left-most digit(s) of a reference number identifies the figure in which the reference number first appears. The same numbers are used throughout the drawings to refer like features and components.

FIG. 1 illustrates a network implementation of a platform for interactive and non-interactive execution and rendering of templates, in accordance with an embodiment of the present disclosure.

FIG. 2 illustrates the platform, in accordance with an embodiment of the present disclosure.

FIG. 3 illustrates a block diagram for controlling one or more systems and exploring data across the one or more systems connected to the platform, in accordance with an embodiment of the present disclosure.

FIG. 4 illustrates a block diagram for recommending Visual and Execution Templates to enable automation of control and data exploration across multiple systems, in accordance with an embodiment of the present disclosure.

FIG. 5 illustrates a block diagram for interactive and non-interactive execution and rendering of templates, in accordance with an embodiment of the present disclosure.

DETAILED DESCRIPTION

In one embodiment a platform configured for interactive and non-interactive execution and rendering of templates is illustrated. Initially, the platform may be accessed from a user device. In one embodiment, the platform may be configured to establish connection with a set of systems. The set of systems may be registered over a service registry associated with the platform. Further, the platform may be configured to start a new exploration or render existing/saved exploration over a graphical user interface of the user device based on instructions received from the user. Further, the platform may be configured to identify a sub-set of target systems from the set of target systems based on a visual element selected, by the user, in the exploration or inputs provided by the user. Furthermore, the platform may be configured to display a menu over the graphical user interface based on the visual element selected by the user or inputs provided by the user. The menu may be configured to display a set of operations/operation-groups associated with the sub-set of systems. Further, the platform may be configured to identify a target system associated with the operation/operation-group selected by the user from the menu. Further, the platform may be configured to transmit the operation/operation-group execution request to the target system, wherein the operation/operation-group is associated with one of a read operation, a write operation to control the target system, or capture user inputs and perform read or write operation to control the target system based on the captured user inputs. Further, the platform may be configured to receive data from the target system, wherein the data is received in response to execution of the operation or operation-group over the target systems. Further, the platform may be configured to discover a subset of best fit templates, from a set of saved templates or templates generated in real-time, based on the type of data received from the target system and a set of predefined rules, wherein the subset of best fit templates enables transmitting data to the target system to write back to the target system in order to control the target system and receiving data from target system for data visualization and analysis.

In one embodiment, the platform is further configured for executing and rendering templates to enable automation of control and data exploration across multiple systems in an interactive and non-interactive mode. Initially, the platform is configured to determine if the set of matching templates is a null set. In case if set of matching templates is not a null set, platform is configured to add some templates to the view panel and some to the exploration directly. In one embodiment the decision, to add a template to view panel or directly in the exploration, may be taken on the basis of various attributes for example type of data, popularity, relevance, environment variables, user configurations, or user choices about the discovered templates. In one embodiment templates added to the view panel may be rendered on the GUI. Further, platform is configured to rank the list of templates in view panel on the basis of one or more meta properties of templates for example, creator, publisher, type of data contained, type of visualizations, popularity, relevance, expected execution/completion time, operations, operation input parameters etc. Additional properties may be used to rank, for example user's choice, user configurations, environment variables etc. In one embodiment view panel may display several attributes of templates in the view panel to provide their summary to the user. In one embodiment user may choose to add, execute and render a template to the exploration through GUI. In one embodiment templates may be added, executed, and rendered automatically by the system. In one embodiment a template can be added in the exploration for interactive or non-interactive execution. Platform is configured to add template to the exploration either on user request or system driven request. Further, platform is configured to execute the template by extracting execution model from the template. Execution model is a graph representation of the operation exploration stored in the template's definition. An execution plan is generated from the execution model. Platform is further configured to generate instructions to run the execution plan. System is configured to run the execution plan in interactive or non-interactive mode based on the instructions. While executing the execution plan, for each operation in the execution plan, execution engine is configured to determine if user input is required or not. If user input is required and plan is running in interactive mode, then a command is sent to the GUI. The GUI prompts the user to provide inputs for the operation to be executed. System is further configured to render a wizard or use interactive UI element to capture user input. Further, user provided inputs are sent to the execution engine to execute the current operation with the user provided inputs. System is further configured to receive data generated by the target systems in response to the operation executed by the execution engine. On receiving the data from target systems in the data store, the system is configured to visualize the data on the template rendered on the GUI.

While aspects of the described platform for executing and rendering templates to enable automation of control and data exploration across multiple systems in an interactive and non-interactive mode may be implemented in any number of different computing systems, environments, and/or configurations, the embodiments are described in the context of the following exemplary platform.

Referring now to FIG. 1, a network implementation 100 of a platform 102 for interactive and non-interactive execution and rendering of templates is disclosed. Although the present disclosure is explained considering that the platform 102 is implemented on a server, it may be understood that the platform 102 may also be implemented in a variety of computing systems, such as a laptop computer, a desktop computer, a notebook, a workstation, a mainframe computer, a server, a server cluster, distributed servers, a network server, and the like. In one implementation, the platform 102 may be implemented in a cloud-based environment. It will be understood that the platform 102 may be accessed by multiple users through one or more user devices 104-1, 104-2 . . . 104-N, collectively referred to as user devices 104 hereinafter, or applications residing on the user devices 104. Examples of the user devices 104 may include, but are not limited to, a portable computer, a personal digital assistant, a handheld device, and a workstation. The user devices 104 are communicatively coupled to the platform 102 through a first network 106. Further, the platform 102 is connected to a set of external systems and databases 110 through a second network 112. In one embodiment, each system from the set of external systems and databases 110 may be configured to gather, process and maintain data. In one embodiment, each system from the set of external systems and databases 110 may be connected to the platform through connectors 108. Each connector is configured to connect one or more systems to the platform 102. Once the systems 110 are connected to the platform 102, the user may control these external systems and databases 110 or explore data across these systems. In one embodiment, the connector 108 may be a connector 108 configured to connecting to multiple systems based on the configuration of the connector 108.

In one implementation, the first network 106 and second network 112 may be a wireless network, a wired network or a combination thereof. The first network 106 and the second network 112 can be implemented as one of the different types of networks, such as intranet, local area network (LAN), wide area network (WAN), the internet, and the like. The first network 106 and second network 112 may either be a dedicated network or a shared network. The shared network represents an association of the different types of networks that use a variety of protocols, for example, Hypertext Transfer Protocol (HTTP), Transmission Control Protocol/Internet Protocol (TCP/IP), Wireless Application Protocol (WAP), and the like, to communicate with one another. Further the first network 106 and second network 112 may include a variety of network devices, including routers, bridges, servers, computing devices, storage devices, and the like. The platform 102 may further be configured to perform data analysis and visualization using the data received from one or more systems from the set of external systems and databases 110. The working of the platform 102 for interactive and non-interactive execution and rendering of templates is further explained with reference to FIG. 2.

Referring now to FIG. 2, the platform 102 is illustrated in accordance with an embodiment of the present disclosure. In one embodiment, the platform 102 may be implemented using at least one processor 202, an input/output (I/O) interface 204, and a memory 206. The at least one processor 202 may be implemented as one or more microprocessors, microcomputers, microcontrollers, digital signal processors, central processing units, state machines, logic circuitries, and/or any devices that manipulate signals based on operational instructions. Among other capabilities, the at least one processor 202 is configured to fetch and execute computer-readable instructions stored in the memory 206.

The I/O interface 204 may include a variety of software and hardware interfaces, for example, a web interface, a graphical user interface, and the like. The I/O interface 204 may allow the platform 102 to interact with a user directly or through the client devices 104. Further, the I/O interface 204 may enable the platform 102 to communicate with other computing devices, such as web servers and external data servers and the set of external systems and databases 110. The I/O interface 204 can facilitate multiple communications within a wide variety of networks and protocol types, including wired networks, for example, LAN, cable, etc., and wireless networks, such as WLAN, cellular, or satellite. The I/O interface 204 may include one or more ports for connecting a number of devices to one another or to another server.

The memory 206 may include any computer-readable medium known in the art including, for example, volatile memory, such as static random access memory (SRAM) and dynamic random access memory (DRAM), and/or non-volatile memory, such as read only memory (ROM), erasable programmable ROM, flash memories, hard disks, optical disks, and magnetic tapes. The memory 206 may include modules 208 and data 210.

The modules 208 include routines, programs, objects, components, data structures, etc., which perform particular tasks, functions or implement particular abstract data types. In one implementation, the modules 208 may include an Operation Client 212, a Rendering Engine 214, an Execution manager 216, an Execution Engine 218, a Service Repository 220, a Data Store 222, an Exploration Client 224, an Exploration Module 226, a Transformation Service Module 228, a Result-set Store 230, a Template Discovery Engine 232, a Template Repository 234, and other modules 236. The other modules 236 may include programs or coded instructions that supplement applications and functions of the platform 102.

The data 210, amongst other things, serves as a repository for storing data processed, received, and generated by one or more of the modules 208. The data 210 may also include a data store 222, and other data 240. In one embodiment, the data store 222 may be configured to store data generated by the set of external systems and databases 110. In one embodiment, the Data Store 222 may be configured to store data generated by one or more modules 208. In one embodiment, the other data 240 may include data generated as a result of the execution of one or more modules in the modules 208. In one embodiment, the other data 240 may include data generated as a result of the execution of one or more modules in the other modules 236.

In one implementation, the platform 102 may be configured to connect with a set of external systems and databases 110 (may also be referred as systems 110) through the second network 112. The user may register using the I/O interface 204 in order to use the platform 102. Once the user is registered, the user may use the client device 104 to access the platform 102 via the I/O interface 204. Once the user registers and is connected to the platform, the user may access different modules implemented over the platform and perform one or more operations and formulas.

Initially, the Graphical User Interface (GUI) over the user device 104 may enable the user to communicate with the platform 102 using the I/O interface 204. The I/O interface 204 may enable the user to create a new exploration or open an existing/saved exploration. The new exploration may correspond to a new folder, an old folder, an existing file, or a new file, a web browser, an analytics report and the like. In one embodiment, the existing/saved exploration may also correspond analytics operations/new analytics operation initiated by a user over the web browser or an offline tool.

The user may interact with the platform 102 through the GUI and select an element in the new exploration or the existing/saved exploration. The element may correspond to a graph, text, text box, command button, background, or any other visual element present on the existing/saved exploration. In one embodiment, context information associated with the user is determined based on the element selected by the user or inputs provided by the user.

The operation client 214 is configured to receive the context information. The context information is determined based on a visual element selected, by the user, in the exploration or inputs provided by the user. The user may provide inputs by entering a keyword in the exploration.

The service registry 220 may be configured to discover the set of operations associated with each system from the set of external systems and databases 110 based on context information to identify a subset of systems and a subset of operations based on the context information. The subset of operations may comprise individual operations and/or composite operations. In one embodiment, a composite operation may be a group of operations that may contain one or more operations provided by the target systems.

The GUI may render a menu on the user device 204. The menu may comprise the subset of operations. In one embodiment, the menu may be displayed in the form of a dropdown with subset of operations for the selection of the user.

The user may choose a target operation from the subset of operations displayed in the menu. In one embodiment, the user may choose more than one operation/composite operations from the subset of operations displayed in the menu as the target operation.

Once the target operation is selected, the operation client 212 is configured to handle the target operation selected by the user and transmit a request to the execution manager 216 to execute the target operation.

The execution manager 216 is configured to generate an execution plan for the target operation. The execution plan may represent a sequence in which the target operation should be executed and the information required for execution of the target operation. Execution plan is a graph of operations and formulas, wherein each node of the graph represents an operation to be executed on the target system.

The execution plan may be executed by the execution engine 218, by sending operation and its context based parameters to the connector 108 of the target system. While executing the execution plan, execution engine 218 may send the target operation to the target systems in parallel (i.e. concurrently) or sequentially (i.e. one after the other).

The target system may be configured to determine if the operation parameters received from the execution engine 218 is sufficient to execute the target operation.

If the operation parameters received from the execution engine 218 is not sufficient for execution of the target operation, the target system may be configured to generate the form's meta information. The form's meta information is sent to execution engine 218. The form's meta information may enable generation of a form to accept user inputs for the missing parameters of target operations or information related to the target operations.

The execution engine 218 may use the form's meta information to create a form node. The form node is exploration compatible (i.e. the form node may be placed and rendered in an exploration). Once the form node is generated, the form node is sent to the exploration module 226. The exploration module 226 is configured to add the exploration node to the current exploration associated with a new exploration or the existing/saved exploration.

The rendering engine 214 is configured to receive change event from exploration module 226. Further, the rendering engine 214 may be configured to send instructions to the user device 104 to render a user input form over the GUI. The user input form is generated based on the meta information.

The GUI 204 is configured to render the user input form. Further, the user may fill up all the necessary fields in the user input form and clicks on a command button from a set of command buttons. Each command button may be associated with different system from the set of systems or different operations associated with the target systems.

If the clicked command button is associated with another operation of any target system, then the execution is once again transferred to the operation client 212 to handle another operation in the same way as the target operation.

If the clicked command button is not associated with another operation of the different system, Operation Client 212 is configured to gather user inputs received from the user input form and transfer these user inputs to the execution engine 218. The user inputs may be in the form of threshold parameters, predefined criteria's, or any other information generally used for analysis purpose.

The execution engine 218 is configured to transmit the user inputs received from the user to the target system through the connector 108.

If the information/user inputs received from the execution engine 218 are sufficient, the target system may be configured to execute the target operation. Based on the execution of the target operation, the target system may or may not generate new data.

If new data is generated, the execution engine 218 is configured to receive the type of the new data generated by the target systems. Execution engine 218 is configured to request Execution Handler 238 to determine the destination data container. For example, the type of new data may be structure data, unstructured data, analytics data, visual data and the like.

The Execution Handler 238 is configured to define the destination data container for the new data. Execution Handler 238 may be configured to find a data container of data store 222 where this data can be added/replaced, based on exploration chain or user configuration. If an existing data container has been identified to be reused, then the existing data container is assigned as the destination data container. In another embodiment, the Execution Handler 238 is configured to send a request to the Data Store 222 to create a new empty data container for this type of data. The newly created data container becomes the destination data container.

The Execution Handler 238 is configured to send a request to the target system 110 with the identity of the destination data container of data store 222. The target system is configured to route the new data to the destination container of the data store 222. Data store 222 is configured to store the data provided by the target systems. The Connector 108 is configured to publish an event that the data has been changed in the destination container so that all the subscribers/listeners of this data change event can act accordingly. In one embodiment, a module may be configured to identify these events and accordingly create variety of visualizations on the GUI using the newly generated data. In another embodiment, the event may be identified by comparing the magnitude of change in the destination container with a predefined threshold change stored in the data store 222. It is to be noted that the connector 108 may be configured to notify one or more external systems and databases 110 associated to the event. Furthermore, the module may be configured to generate new data by calculating formulas based on the currently generated data or earlier generated data. Furthermore, the module may be configured to execute a chain of operations to update the dependent chain of operations on this change event. The chain of operations and formulas are executed during or after execution of the target operation.

In one embodiment, if the new data is generated in response to user selected operation/operation-group, then the execution engine 218 is configured to receive the type of the new data generated by the target systems. Execution engine 218 is configured to request Execution Handler 238 to determine the destination data container.

Further, the Execution Handler 238 is configured to determine if any existing data container can be reused to append or replace the newly generated data. Execution handler 238 may be configured to determine this based on exploration chain, user's choice, or configuration and the like. If an existing data container cannot be reused, then Execution Handler 238 requests the Template Discovery Engine 232 to search for best fit templates for the received data set type.

Further, the Template Discover Engine 232 is configured to Query the Template Repository 234 to identify all the best fit templates suitable for representing the ‘type of data’ associated with the new data. In one embodiment, a subset of best fit templates is discovered by the execution handler from a set of saved templates or templates generated in real-time based on the type of data received from the target system and a set of predefined rules. The subset of best fit templates enables transmitting data to the target system to write back to the target system in order to control the target system and receiving data from target system for data visualization and analysis.

In one embodiment, the Template Repository 234 is configured to analyse a set of templates, saved in the Template Repository 234, based on either the ‘type of data’, ‘user inputs’, ‘environment variables alone or in combination to discover a subset of matching templates/best fit templates applicable for the current user. In one embodiment, the set of templates may comprise:

Templates created by the user

Templates published to the user by other users

Templates recommended by the system for the user (on the basis of past behaviour of users or other system parameters). In other words, the template repository is configured to maintain the set of saved templates. The set of saved templates comprise of one or more templates created by the user, one or more templates published by other users of the platform, and one or more system generated templates. The system generated templates are generated based on analysis of explicit feedback provided by user or templates generated based on the set of predefined rules. The set of predefined rules comprise implicit feedback captured from users’ behavior, wherein the users' behavior is derived from users' usage patterns, time spent by user with certain visualizations or data, and computations performed by user on the data. The set of predefined rules may also comprise a set of parameters including, but not limited to, User's default template, Most frequently used by the user/team/organization, Longevity of usage, Most recently used by the user, Most relevant based on User's usage history, location, role, and Type and structure of the data received from target system. In one implementation, the set of predefined rules may be generated by using machine learning techniques on the implicit feedback captured from users' behavior and the set of parameters.

Further, execution handler 238 is configured to receive the set of matching templates/best fit templates and default visualizations corresponding to the type of data, user inputs, environment variables or a combination thereof. Further, execution handler is configured to send a request to Exploration module 226 to add these templates in the current exploration. Further, the execution handler 238 is configured to rank the subset of best fit templates from the set of saved templates or templates generated in real-time based on predefined criteria's, wherein the predefined criteria's comprise best outcomes, popularity, relevance, creators, type of exploration or expected execution time, and wherein the real-time templates are generated using AI and Machine learning

The Exploration module 226 is configured to add the received templates and default visualizations to a view panel or exploration pages for the purpose of execution of templates on the GUI. In one embodiment, the templates may be added to the exploration pages on the basis of meta attributes of the template like confidence score, popularity, relevance, expected time of execution etc. The user may view the set of matching templates and various visualizations on the view panel.

Further, the Exploration module 226 is configured to add all the discovered templates and default visualizations to the Graphical User Interface (GUI) (i.e. Users screen/view panel and/or exploration pages). Further to adding templates to the view panel and/or exploration pages, Exploration module 226 is configured to raise an exploration change event.

Further, upon triggering of the exploration change event, the Rendering Engine 214 is configured to receive the exploration change event notification. Further, Rendering Engine 214 sends command to GUI to refresh the view panel. Further, GUI is refreshed so that the newly added templates and default visualizations are visible in the view panel. Further, the resultant template list may be ranked by the Rendering Engine 214 on the basis of one or more meta properties of the templates for example, owner, publisher, type of data contained, type of visualizations, popularity, relevance, expected execution/completion time, operations, operation input parameters etc. The view panel may also use additional properties while ranking for example user's choice, user configurations, environment variables, machine learning algorithms, etc.

The GUI may be configured to display several attributes of the templates in the view panel to help user get a summary of all the templates listed in the view panel. Further, these attributes may help the user to choose which template to add, execute and render in the exploration at a later stage.

Further, the user may interact with the GUI to add, execute and render a template on the exploration. In one embodiment user may choose to execute the template in interactive or non-interactive mode. In one embodiment a subset of templates, from the set of discovered templates, may be added, executed and rendered without user intervention as well. Further, the decision to add the template directly to the exploration may be basis on the type of data, popularity, relevance, environment variables, user configurations, user choices or a combination thereof.

Further, the Exploration Client 224 may receive a command from the GUI to add the template to the exploration. Further, GUI sends the mode of execution, interactive or non-interactive, of the template to the Exploration Client.

Further, the Exploration Client 224 may forward the command to the Exploration Module 226 to move the template from view panel to the exploration pages.

In one embodiment, Exploration Module 226 is configured to remove the template from view panel and add the template to one or more requested exploration pages.

Further, the Exploration Module 226 may be configured to raise a notification event to announce the change in the exploration so that all the listeners interested in this event can receive the event. In one embodiment, the listeners may be other instances of this exploration shared with other users for real-time refresh and execution of the explorations.

Further, the Rendering Engine 214 is configured to detect the exploration change event and request the GUI to render the template on the exploration pages. Further, GUI may render the template by rendering the layout of the template first. Further, all the visualizations contained within the template may also be rendered.

Further, the Exploration Module 226 is configured to extract the Execution model from the template. Execution model is a graph of operations that were stored in the template at the time of template creation. In one embodiment, the execution model may be a graph of formulas stored in the template at the time of template creation.

Further, the Exploration Module 226 is configured to send a request to Execution Handler 238 to execute the extracted execution model.

The Execution Handler 238 may construct an execution plan using this execution model. Execution plan is a graph of operations. Each node of the graph represents an operation to be executed on the target system 110. Further, Execution Handler 238 submits the constructed execution plan to Execution Engine 218 to start the plan execution.

The Execution Engine 218 may execute the execution plan. Further, before sending each operation of the execution plan to target system for execution, execution engine 218 may determine if user input is required to execute the current operation.

If user input is required, the Execution engine 218 may send a command to the rendering engine 214 to request for input from user. Further, the request is received by the GUI.

Further, the rendering engine 214 may prompt the user over the GUI for receiving inputs. The rendering engine 214 may render a wizard over the GUI to seek user input interactively.

Further, the user provided inputs may be captured by the GUI and sent to the Execution Engine 218 via Operation Client 212.

Further, the Execution Engine 218 may use the received operation parameters to send a command to Target Systems to execute the current operation of the execution plan.

In one embodiment, the Target System may provide a response to the operation execution request, when some data is available as a result of executed operation.

The Execution Handler 238 may send a request to Target systems to route available data to the specified data container of Data Store 222. Further, Target systems 110 may route the data generated by the operation to the specified destination data container in the Data Store 222 via the Execution Handler 238. The Execution Handler 238 may act as a temporary cache to reduce load on the Data Store 222.

Furthermore, as the data is routed by the target system to the data store 222, via the Execution Handler 238, a data change event may be raised by the Execution Handler 238 or the data store 222.

Once the data change event is generated, the Rendering Engine 214 may send a command to GUI to refresh the visualizations of the rendered template associated with the generated data.

Further, The GUI may send a data transformation definition associated with the visualization to the rendering engine 214. Further rendering client, sends that command to Transformation Service Module 228.

Further, the Transformation Service Module 214 may create a Data Transformation query from the Data Transformation definition. Further, the data transformation query is sent to the Data Store 222.

Further, the Data Store 222 may return the data stored in the Data store 222 matching the provided data transformation query to the Transformation Service Module 214. Further, the Transformation Service Module 214 stores the received data in the Result Set Store 230.

In one embodiment, the Result Set Store 230 may raise a data change notification. Further, the data change notification is received by the Rendering Engine 214.

Further, the Rendering Engine 214 may send a command to GUI to refresh the visualization associated with the Result Set Store 230. The process of controlling one or more systems and exploring data across the one or more systems connected to the platform 102 is further elaborated with respect to the block diagram of FIG. 3.

Referring now to FIG. 3, a method 300 for controlling one or more systems and exploring data across the one or more external systems and databases 110 connected to the platform 102 is illustrated, in accordance with an embodiment of the present disclosure. The method 300 may be described in the general context of computer executable instructions. Generally, computer executable instructions can include routines, programs, objects, components, data structures, procedures, modules, functions, and the like, that perform particular functions or implement particular abstract data types. The method 300 may also be practiced in a distributed computing environment where functions are performed by remote processing devices that are linked through a communications network. In a distributed computing environment, computer executable instructions may be located in both local and remote computer storage media, including memory storage devices.

The order in which the method 300 is described is not intended to be construed as a limitation, and any number of the described method blocks can be combined in any order to implement the method 300 or alternate methods. Additionally, individual blocks may be deleted from the method 300 without departing from the spirit and scope of the disclosure described herein. Furthermore, the method can be implemented in any suitable hardware, software, firmware, or combination thereof. However, for ease of explanation, in the embodiments described below, the method 300 may be considered to be implemented in the above described platform 102.

In one embodiment, at step 302, the Graphical User Interface (GUI) over the user device 104 may enable the user to communicate with the platform 102 using the I/O interface 204. The I/O interface 204 may enable the user to create a new exploration or open an existing/saved exploration. The new exploration may correspond to a new folder, an old folder, an existing file, or a new file, a web browser, an analytics report and the like. In one embodiment, the existing/saved exploration may also correspond analytics operations/new analytics operation initiated by a user over the web browser or an offline tool.

At step 304, the user may interact with the platform 102 through the GUI and select an element in the new exploration or the existing/saved exploration. The element may correspond to a graph, text, text box, command button, background, or any other visual element present on the existing/saved exploration. In one embodiment, context information associated with the user is determined based on the element selected by the user or inputs provided by the user.

At step 306, the operation client 214 is configured to receive the context information. The context information is determined based on a visual element selected, by the user, in the exploration or inputs provided by the user. The user may provide inputs by entering a keyword in the exploration.

At step 308, the service registry 220 may be configured to discover the set of operations associated with each system from the set of external systems and databases 110 based on context information to identify a subset of systems and a subset of operations based on the context information. The subset of operations may comprise individual operations and/or composite operations. In one embodiment, a composite operation may be a group of operations that may contain one or more operations provided by the target systems.

At step 310, the GUI may render a menu on the user device 204. The menu may comprise the subset of operations. In one embodiment, the menu may be displayed in the dorm of a dropdown with subset of operations for the selection of the user.

At step 312, the user may choose a target operation from the subset of operations displayed in the menu. In one embodiment, the user may choose more than one operation/composite operations from the subset of operations displayed in the menu as the target operation.

At step 314, once the target operation is selected, the operation client 212 is configured to handle the target operation selected by the user and transmit a request to the execution manager 216 to execute the target operation.

At step 316, the execution manager 216 is configured to generate an execution plan for the target operation. The execution plan may represent a sequence in which the target operation should be executed and the information required for execution of the target operation. Execution plan is a graph of operations, wherein each node of the graph represents an operation to be executed on the target system 110.

At step 318, the execution plan may be executed by the execution engine 218, by sending operation and its context based parameters to the connector of the target system. While executing the execution plan, execution engine 218 may send the target operation to the target systems in parallel (i.e. concurrently) or sequentially (i.e. one after the other).

At step 320, the target system may be configured to determine if the operation parameters received from the execution engine 218 is sufficient to execute the target operation.

At step 322, if the operation parameters received from the execution engine 218 is not sufficient for execution of the target operation, the target system may be configured to generate the form's meta information. The form's meta information is sent to execution engine 218. The form's meta information may enable generation of a form to accept user inputs for the missing parameters of target operations or information related to the target operations.

At step 324, the execution engine 218 may use the form's meta information to create a form node. The form node is exploration compatible (i.e. the form node may be placed and rendered in an exploration). Once the form node is generated, the form node is sent to the exploration module 226. The exploration module 226 is configured to add the exploration node to the current exploration associated with a new exploration or the existing/saved exploration.

At step 326, rendering engine 214 is configured to receive change event from exploration module 226. Further, the rendering engine 214 may be configured to send instructions to the user device 104 to render a user input form over the GUI. The user input form is generated based on the meta information.

At step 328, the GUI 204 is configured to render the user input form. Further, the user may fill up all the necessary fields in the user input form and clicks on a command button from a set of command buttons. Each command button may be associated with different system from the set of systems or different operations associated with the target systems.

At step 330, if the clicked command button is associated with another operation of any target system, then the execution is once again transferred to step 314.

At step 332, if the clicked command button is not associated with another operation of the different system, Operation Client 212 is configured to gather user inputs received from the user input form and transfer these user inputs to the execution engine 218. The user inputs may be in the form of threshold parameters, predefined criteria's, or any other information generally used for analysis purpose.

At step 334, the execution engine 218 is configured to transmit the user inputs received from the user to the target system through the connector 108.

At step 336, if the information/user inputs received from the execution engine 218 are sufficient, the target system may be configured to execute the target operation. Based on the execution of the target operation, the target system may or may not generate new data.

At step 338, if new data is generated, the execution engine 218 is configured to receive the type of the new data generated by the target systems. Execution engine 218 is configured to request Execution Handler 238 to determine the destination data container. For example, the type of new data may be structure data, unstructured data, analytics data, visual data and the like.

At step 340, the Execution Handler 238 is configured to define the destination data container for the new data. Execution Handler 238 may be configured to find a data container of data store 222 where this data can be added/replaced, based on exploration chain or user configuration. If an existing data container has been identified to be reused, then the existing data container is assigned as the destination data container. In another embodiment, the Execution Handler 238 is configured to send a request to Data Store 222 to create a new empty data container for this type of data. The newly created data container becomes the destination data container.

At step 342, the Execution Handler 238 is configured to send a request to the target system with the identity of the destination data container of data store 222. The target system is configured to route the new data to the destination container of the data store 222. Data store 222 is configured to store the data provided by the target systems. Data store 222 is configured to publish an event that the data has been changed in the destination container so that all the subscribers/listeners of this data change event can act accordingly. In one embodiment, a module may be configured to identify these events and accordingly create variety of visualizations on the GUI using the newly generated data. In another embodiment, the event may be identified by comparing the magnitude of change in the destination container with a predefined threshold change stored in the data store 222. It is to be noted that the connector 108 may be configured to notify one or more external systems and databases 110 associated to the event. Furthermore, the module may be configured to generate further new data by calculating formulas based on the currently generated data or earlier generated data. Furthermore, the module may be configured to execute a chain of operations to update the dependent chain of operations on this change event. The process of recommending Visual and Execution Templates to enable automation of control and data exploration across multiple systems is further elaborated with reference to block diagram of FIG. 4.

Referring now to FIG. 4, a method 400 for recommending Visual and Execution Templates to enable automation of control and data exploration across multiple systems is illustrated, in accordance with an embodiment of the present disclosure. The method 400 may be described in the general context of computer executable instructions. Generally, computer executable instructions can include routines, programs, objects, components, data structures, procedures, modules, functions, and the like, that perform particular functions or implement particular abstract data types. The method 400 may also be practiced in a distributed computing environment where functions are performed by remote processing devices that are linked through a communications network. In a distributed computing environment, computer executable instructions may be located in both local and remote computer storage media, including memory storage devices.

The order in which the method 400 is described is not intended to be construed as a limitation, and any number of the described method blocks can be combined in any order to implement the method 400 or alternate methods. Additionally, individual blocks may be deleted from the method 400 without departing from the spirit and scope of the disclosure described herein. Furthermore, the method can be implemented in any suitable hardware, software, firmware, or combination thereof. However, for ease of explanation, in the embodiments described below, the method 400 may be considered to be implemented in the above described platform 102.

At step 402, if the new data is generated in response to user selected operation/operation-group, then the execution engine 218 is configured to receive the type of the new data generated by the target systems 110. Execution engine 218 is configured to request Execution Handler 238 to determine the destination data container.

At step 404, the Execution Handler 238 is configured to determine if any existing data container can be reused to append or replace the newly generated data. Execution handler 238 may be configured to determine this based on exploration chain, user's choice, or configuration and the like. If an existing data container cannot be reused, then Execution Handler 238 requests the Template Discovery Engine 232 to search for best fit templates for the received data set type.

At step 406, the Template Discover Engine 232 is configured to Query the Template Repository 234 to identify all the best fit templates suitable for representing the ‘type of data’ associated with the new data. In one embodiment, a subset of best fit templates is discovered by the execution handler from a set of saved templates or templates generated in real-time based on the type of data received from the target system and a set of predefined rules. The subset of best fit templates enables transmitting data to the target system to write back to the target system to control target systems and receiving data from target system for data visualization and analysis.

At step 408, the Template Repository 234 is configured to analyse a set of templates, saved in the Template Repository 234, based on either the ‘type of data’, ‘user inputs’, ‘environment variables alone or in combination to discover a subset of matching templates/best fit templates applicable for the current user. In one embodiment, the set of templates may comprise:

Templates created by the user

Templates published to the user by other users

Templates recommended by the system for the user (on the basis of past behaviour of users or other system parameters). In other words, the template repository is configured to maintain the set of saved templates. The set of saved templates comprise of one or more templates created by the user, one or more templates published by other users of the platform, and one or more system generated templates. The system generated templates are generated based on analysis of explicit feedback provided by user or templates generated based on the set of predefined rules. The set of predefined rules comprise implicit feedback captured from users’ behavior, wherein the users' behavior is derived from users' usage patterns, time spent by user with certain visualizations or data, and computations performed by user on the data. The set of predefined rules may also comprise a set of parameters including, but not limited to, User's default template, Most frequently used by the user/team/organization, Longevity of usage, Most recently used by the user, Most relevant based on User's usage history, location, role, and Type and structure of the data received from target system. In one implementation, the set of predefined rules may be generated by using machine learning techniques on the implicit feedback captured from users' behavior and the set of parameters.

At step 410, the Execution handler 238 is configured to receive the set of matching templates/best fit templates and default visualizations corresponding to the type of data, user inputs, environment variables or a combination thereof. Further, the Execution handler 238 is configured to send a request to the Exploration module 226 to add these templates in the current exploration. Further, the Execution handler 238 is configured to rank the subset of best fit templates from the set of saved templates or templates generated in real-time based on predefined criteria's, wherein the predefined criteria's comprise best outcomes, popularity, relevance, creators, type of exploration or expected execution time, and wherein the real-time templates are generated using AI and Machine learning.

At step 412, the Exploration module 226 is configured to add the received templates and default visualizations to a view panel or exploration pages for the purpose of execution of templates on the GUI. In one embodiment, the templates may be added to the exploration pages on the basis of meta attributes of the template like confidence score, popularity, relevance, expected time of execution etc. The user may view the set of matching templates and various visualizations on the view panel. The process of executing and rendering templates to enable automation of control and data exploration across multiple systems in an interactive and non-interactive mode is further elaborated with reference to the block diagram of FIG. 5.

Referring now to FIG. 5, a method 500 for executing and rendering templates to enable automation of control and data exploration across multiple systems in an interactive and non-interactive mode is illustrated, in accordance with an embodiment of the present disclosure. The method 500 may be described in the general context of computer executable instructions. Generally, computer executable instructions can include routines, programs, objects, components, data structures, procedures, modules, functions, and the like, that perform particular functions or implement particular abstract data types. The method 500 may also be practiced in a distributed computing environment where functions are performed by remote processing devices that are linked through a communications network. In a distributed computing environment, computer executable instructions may be located in both local and remote computer storage media, including memory storage devices.

The order in which the method 500 is described is not intended to be construed as a limitation, and any number of the described method blocks can be combined in any order to implement the method 500 or alternate methods. Additionally, individual blocks may be deleted from the method 500 without departing from the spirit and scope of the disclosure described herein. Furthermore, the method can be implemented in any suitable hardware, software, firmware, or combination thereof. However, for ease of explanation, in the embodiments described below, the method 500 may be considered to be implemented in the above described platform 102.

At step 502, the Exploration module 226 is configured to add all the discovered templates and default visualizations to the Graphical User Interface (GUI) (i.e. Users screen/view panel and/or exploration pages). Further to adding templates to the view panel and/or exploration pages, the Exploration module 226 is configured to raise an exploration change event.

At step 504, upon triggering of the exploration change event, the Rendering Engine 214 is configured to receive the exploration change event notification. Further, Rendering Engine 214 sends command to GUI to refresh the view panel. Further, GUI is refreshed so that the newly added templates and default visualizations are visible in the view panel. Further, the resultant template list may be ranked by the Rendering Engine 214 on the basis of one or more meta properties of the templates for example, owner, publisher, type of data contained, type of visualizations, popularity, relevance, expected execution/completion time, operations, operation input parameters etc. The view panel may also use additional properties while ranking for example user's choice, user configurations, environment variables or using machine learning algorithms etc.

At step 506, the GUI may be configured to display several attributes of the templates in the view panel to help user get a summary of all the discovered templates listed in the view panel. Further, these attributes may help the user to choose which template to add, execute and render in the exploration at a later stage.

At step 508, the user may interact with the GUI to add, execute and render a template on the exploration. In one embodiment user may choose to execute the template in interactive or non-interactive mode. In one embodiment a subset of templates, from the set of discovered templates, may be added, executed and rendered without user intervention as well. Further, the decision to add the template directly to the exploration may be basis on the type of data, popularity, relevance, environment variables, user configurations, user choices or a combination thereof.

At step 510, the Exploration Client 224 may receive a command from the GUI to add the template to the exploration. Further, GUI sends the mode of execution, interactive or non-interactive, of the template to the Exploration Client.

At step 512, the Exploration Client 224 may forward the command to the Exploration Module 226 to move the template from view panel to the exploration pages.

At step 514, Exploration Module 226 is configured to remove the template from view panel and add the template to one or more requested exploration pages.

At step 516, the Exploration Module 226 may be configured to raise a notification event to announce the change in the exploration so that all the listeners interested in this event can receive the event. In one embodiment, the listeners may be other instances of this exploration shared with other users for real-time refresh of explorations for other shared user sessions.

At step 518, the Rendering Engine 214 is configured to detect the exploration change event and request the GUI to render the template on the exploration pages. Further, GUI may render the template by rendering the layout of the template first. Further, all the visualizations contained within the template may also be rendered.

At step 520, the Exploration Module 226 is configured to extract the Execution model from the template. Execution model is a graph of operations that were stored in the template at the time of template creation. In one embodiment, the execution model may be a graph of formulas stored in the template at the time of template creation.

At step 522, the Exploration Module 226 is configured to send a request to Execution Handler 238 to execute the extracted execution model.

At step 524, the Execution Handler 238 may construct an execution plan using this execution model. Execution plan is a graph of operations and formulas. Each node of the graph represents an operation to be executed on the target system 110. Further, Execution Handler 238 submits the constructed execution plan to Execution Engine 218 to start the plan execution.

At step 526, the Execution Engine 218 may execute the execution plan. Further, before sending each operation of the execution plan to target system 110 for execution, execution engine 218 may determine if user input is required to execute the current operation.

At step 528, if user input is required, the Execution engine 218 may send a command to the rendering engine 214 to request for input from user. Further, the request is received by the GUI.

At step 530, the rendering engine 214 may prompt the user over the GUI for receiving inputs. The rendering engine 214 may render a wizard over the GUI to seek user input or use navigating, highlighting, marking, flashing any UI element to seek user input interactively.

At step 532, the user may provide input for operation parameters either through a step by step wizard or interaction on the GUI with various visual elements of several visualizations.

At step 534, the user provided inputs may be captured by the GUI and sent to the Execution Engine 218 via Operation Client 212.

At step 536, the Execution Engine 218 may use the received operation parameters to send a command to Target Systems to execute the current operation of the execution plan.

At step 538, the Target System 110 may provide a response to the operation execution request, when some data is available as a result of executed operation.

At step 540, the Execution Handler 238 may send a request to Target systems 110 to route available data to the specified data container of Data Store 222. Further, Target system may route the data generated by the operation to the specified destination data container in the Data Store 222 via the Execution Handler 238. Execution Handler 238 may act as a temporary cache to reduce load on Data Store 222.

At step 542, as the data is routed by the target system to the data store 222, via the Execution Handler 238, a data change event may be raised by the Execution Handler 238 or the data store 222.

At step 544, once the data change event is generated, the Rendering Engine 214 may send a command to GUI to refresh the visualizations of the rendered template associated with the generated data.

At step 546, the GUI may send a data transformation definition associated with the visualization to the rendering engine 214. Further rendering client, sends that command to Transformation Service Module 228.

At step 548, the Transformation Service Module 214 may create a Data Transformation query from the Data Transformation definition. Further the data transformation query is sent to the Data Store 222.

At step 550, the Data Store 222 may return the data stored in the Data store 222 matching the provided data transformation query to Transformation Service Module 214. Further, Transformation Service Module 214 stores the received data in Result Set Store 230.

At step 552, the Result Set Store 230 may raise a data change notification. Further, the data change notification is received by the Rendering Engine 214.

At step 554, Rendering Engine may send a command to GUI to refresh the visualization associated with the Result Set Store 230.

Although implementations for methods and systems executing and rendering templates to enable automation of control and data exploration across multiple systems in an interactive and non-interactive mode have been described, it is to be understood that the appended claims are not necessarily limited to the specific features or methods described. Rather, the specific features and methods are disclosed as examples of implementations for executing and rendering templates to enable automation of control and data exploration across multiple systems in an interactive and non-interactive mode. 

1. A platform (102) for interactive and non-interactive execution and rendering of templates, wherein the platform (102) comprises: a memory (206); and a processor (202) coupled to the memory (206), wherein the processor (202) is configured to execute program instructions, associated with one or more modules (208), stored in the memory (206) for: establishing connection with a set of external systems and databases (110); rendering a new exploration or render an existing exploration over a graphical user interface based on user inputs; identifying a sub-set of systems from the set of external systems and databases (110) based on a context information; displaying a set of operations/operation-groups associated with the sub-set of systems based on the context information; identifying target systems associated with a target operation/operation-group selected by the user; transmitting the target operation/operation-group execution request to the target system, wherein the target operation/operation-group is associated with one of a read operation, a write operation to control the target systems, a capture user inputs and perform one of read and write operation to control the target systems based on the user inputs; receiving data from the target system, wherein the data is received in response to execution of the operation or operation-group over the target system; discovering a subset of best fit templates, from a set of saved templates or templates generated in real-time, based on the type of data received from the target system and a set of predefined rules, wherein the subset of best fit templates enables transmitting data to the target system to write back to the target system to control the target systems and receiving data from target system for data visualization; displaying a set of attributes associated with the subset of best fit templates; rendering a target template from the subset of best fit templates on the new exploration or existing exploration based on user inputs or based on one or more predefined rules from the set of predefined rules, wherein the template is rendered in interactive or non-interactive mode; generating a notification event, wherein the notification event is indicative of change in the exploration; transmitting the notification event to one or more listeners interested in the target template; rendering the target template on the new exploration or existing exploration; executing the target template by extracting execution model from the target template, wherein the execution model is a graph representing the set of operations stored in a definition of the target template; generating instructions to run an execution plan, wherein the execution plan is generated based on the set of operations stored; executing each operation from the execution plan in interactive or non-interactive mode; prompting the user to provide inputs for a current operation to be executed when user input is required for execution of the operation, wherein an interactive UI element is rendered to capture the user input, wherein each operation from the execution plan is execute based on the user provided inputs; receiving data generated by the target system in response to the operation executed; and visualize the data on the template rendered on the GUI based on the data received from target system in the data store.
 2. The platform (102) of claim 1, wherein the set of systems are registered over a service registry.
 3. The platform (102) of claim 1, wherein the context information is determined based on a visual element selected, by the user, in the exploration or inputs provided by the user.
 4. The platform (102) of claim 1, wherein the Graphical User Interface (GUI) is configured to render a menu on a user device, wherein the menu comprises the subset of operations.
 5. The platform (102) of claim 1 is further configured to generate an execution plan for the target operation, wherein the execution plan is a graph of operations, wherein each node of the graph represents an operation to be executed on the target system.
 6. The platform (102) of claim 5, wherein the target system is configured to generate a form's meta information to enable generation of a form to accept user inputs for missing piece of information, when the information received from the execution engine is not sufficient for execution of the target operation.
 7. The platform (102) of claim 6, wherein the form's meta information is used to create a form node, wherein the form node is exploration compatible, wherein an exploration node corresponding to the form node is added to the current exploration associated with a new exploration or the existing/saved exploration.
 8. The platform (102) of claim 7, wherein the target system is configured to send instructions to the user device to render a user input form over the GUI, wherein the user input form is generated based on the form's meta information, wherein the user input form is generated upon receiving a change event.
 9. The platform (102) of claim 8, wherein user inputs received from the user input form are analysed and execution is transferred to the target system, when the user inputs on the user input form corresponds to an operation associated with the target system, and wherein the execution is transferred to another system when the user inputs on the user input form corresponds to an operation associated with the other system.
 10. The platform (102) of claim 9, wherein the target system is configured to execute the target operation when the information/user inputs received from the user are sufficient.
 11. The platform (102) of claim 10 further configured to receive the type of the new data generated by the target system and determine the destination data container, when new data is generated upon execution of the target operation.
 12. The platform (102) of claim 11 further configured to define the destination data container for the new data, or identify a data container of data store where this data can be added or replaced, based on exploration chain or user configuration, when an existing data container is identified to be reused, then the existing data container is assigned as the destination data container.
 13. The platform (102) of claim 12 further configured to send a request to the target system with the identity of the destination data container of data store (222), and wherein the target system is configured to route the new data to the destination container of the data store (222), wherein the data store (222) is configured to store the new data provided by the target system, and publish a change event corresponding to change in the destination container.
 14. The platform (102) of claim 10 further configured to execute a chain of operations on the target system based on execution of the target operation, wherein the chain of operations is executed during or after execution of the target operation.
 15. The platform (102) of claim 1 further comprising steps for ranking the subset of best fit templates from the set of saved templates or templates generated in real-time based on predefined criteria's, wherein the predefined criteria's comprise best outcomes, popularity, relevance, creators, type of exploration or expected execution time and wherein the real-time templates are generated using AI and Machine learning.
 16. The platform (102) of claim 1, wherein the template repository is configured to maintain the set of saved templates, wherein the set of saved templates comprise of one or more templates created by the user, one or more templates published by other users of the platform, and one or more system generated templates,
 17. The platform (102) of claim 1, wherein the system generated templates are generated based on analysis of explicit feedback provided by user, wherein system generated templates are templates generated based on the set of predefined rules, wherein the set of predefined rules comprise implicit feedback captured from users' behavior, wherein the users' behavior is derived from users' usage patterns, time spent by user with certain visualizations or data, and computations performed by user on the data.
 18. The platform (102) of claim 1, wherein the set of predefined rules comprise User's default template, Most frequently used by the user/team/organization, Longevity of usage, Most recently used by the user, Most relevant based on User's usage history, location, role, Type and structure of the data received from target system.
 19. A method for interactive and non-interactive execution and rendering of templates, wherein the method comprises steps for: establishing, by a processor (202), connection with a set of external systems and databases (110); rendering, by the processor (202), a new exploration or render an existing exploration over a graphical user interface based on user inputs; identifying, by the processor (202), a sub-set of systems from the set of external systems and databases (110) based on a context information; displaying, by the processor (202), a set of operations/operation-groups associated with the sub-set of systems based on the context information; identifying, by the processor (202), a target system associated with a target operation/operation-group selected by the user; transmitting, by the processor (202), the target operation/operation-group execution request to the target system, wherein the target operation/operation-group is associated with one of a read operation, a write operation to control the target system, or a capture user inputs and perform one of read and write operation to control the target system based on the user inputs; receiving, by the processor (202), data from the target system, wherein the data is received in response to execution of the operation or operation-group over the target system; discovering, by the processor (202), a subset of best fit templates, from a set of saved templates or templates generated in real-time, based on the type of data received from the target system and a set of predefined rules, wherein the subset of best fit templates enables transmitting data to the target system to write back to the target system in order to control the target system and receiving data from the target system for data visualization; displaying, by the processor (202), a set of attributes associated with the subset of best fit templates; rendering, by the processor (202), a target template from the subset of best fit templates on the new exploration or existing exploration based on user inputs or based on one or more predefined rules from the set of predefined rules, wherein the template is rendered in interactive or non-interactive mode; generating, by the processor (202), a notification event, wherein the notification event is indicative of change in the exploration; transmitting, by the processor (202), the notification event to one or more listeners interested in the target template; rendering, by the processor (202), the target template on the new exploration or existing exploration; executing, by the processor (202), the target template by extracting execution model from the target template, wherein the execution model is a graph representing the set of operations stored in a definition of the target template. generating, by the processor (202), instructions to run an execution plan, wherein the execution plan is generated based on the set of operations stored; executing, by the processor (202), each operation from the execution plan in interactive or non-interactive mode; prompting, by the processor (202), the user to provide inputs for a current operation to be executed when user input is required for execution of the operation, wherein an interactive UI element is rendered to capture the user input, wherein each operation from the execution plan is execute based on the user provided inputs; receiving, by the processor (202), data generated by the target system in response to the operation executed; and visualize, by the processor (202), the data on the template rendered on the GUI based on the data received from target system in the data store.
 20. A computer program product having embodied thereon a computer program for interactive and non-interactive execution and rendering of templates, the computer program product comprises: a program code for establishing connection with a set of external systems and databases (110); a program code for rendering a new exploration or render an existing exploration over a graphical user interface based on user inputs; a program code for identifying a sub-set of systems from the set of external systems and databases (110) based on a context information; a program code for displaying a set of operations/operation-groups associated with the sub-set of systems based on the context information; a program code for identifying a target system associated with a target operation/operation-group selected by the user; a program code for transmitting the target operation/operation-group execution request to the target system, wherein the target operation/operation-group is associated with one of a read operation, a write operation to control the target system, or capture user inputs and perform one of read and write operation to control the target system based on the captured user inputs; a program code for receiving data from the target system, wherein the data is received in response to execution of the operation or operation-group over the target system; a program code for discovering a subset of best fit templates, from a set of saved templates or templates generated in real-time, based on the type of data received from the target system and a set of predefined rules, wherein the subset of best fit templates enables transmitting data to the target system to write back to the target system in order to control the target system and receiving data from target system for data visualization; a program code for displaying a set of attributes associated with the subset of best fit templates; a program code for rendering a target template from the subset of best fit templates on the new exploration or existing exploration based on user inputs or based on one or more predefined rules from the set of predefined rules, wherein the template is rendered in interactive or non-interactive mode; a program code for generating a notification event, wherein the notification event is indicative of change in the exploration; a program code for transmitting the notification event to one or more listeners interested in the target template; a program code for rendering the target template on the new exploration or existing exploration; a program code for executing the target template by extracting execution model from the target template, wherein the execution model is a graphical representation of the set of operations stored in a definition of the target template; a program code for generating instructions to run an execution plan, wherein the execution plan is generated based on the set of operations stored; a program code for execution each operation from the execution plan in interactive or non-interactive mode; a program code for prompting the user to provide inputs for a current operation to be executed when user input is required for execution of the operation, wherein an interactive UI element is rendered to capture the user input, wherein each operation from the execution plan is execute based on the user provided inputs; a program code for receiving data generated by the target system in response to the operation executed; and a program code for visualize the data on the template rendered on the GUI based on the data received from target system in the data store. 